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Electrical System
When the automotive industry was in its infancy, it used electricity only to ignite
the fuel inside the engine. By the late 1920's, the electric starter replaced the
hand crank, electric headlights made acetylene lamps obsolete and the braying of
the electric horn drowned out the squeak of the hand-squeezed air horn. Today,
an automobile requires an elaborate electrical system of circuits just to produce,
store, and distribute all the electricity it requires simply for everyday operation.
The first major component in the electrical system is the battery. The battery is
used to store power for starting, and for running auxiliary devices such as clocks,
radios and alarms when the engine is off. The next major component is the starter
motor, which is used to start the engine. The third component is a charging device
powered by the engine, known as the alternator. It powers the electrical system when
the car is running, and restores the charge within the battery. With these basic
components, the car maintains its supply of electricity. A device called the
voltage regulator keeps the power level stabilized, and the fuse box keeps minor
problems from becoming major ones.
Many different auxiliary electrical devices are used in modern cars, such as
radios, cellular phones, rear window defrosters and electric door locks,
as well as a vast array of motors powering everything from the moonroof on down.
Battery
The car's initial source of electricity is a battery, whose most important
function is to start the engine. Once the engine is running, an alternator
takes over to supply the car's electrical needs and to restore energy to
the battery.
A 12-volt storage battery consists of layers of positively and negatively
charged lead plates that, together with their insulated separators, make up
each of six two-volt cells. The cells are filled with an electricity-conducting
liquid (electrolyte) that is usually two-thirds distilled water and one-third
sulfuric acid. Spaces between the immersed plates provide the most exposure
to the electrolyte. The interaction of the plates and the electrolyte
produces chemical energy that becomes electricity when a circuit is formed
between the negative and positive battery terminals.
Starter
The starter converts electricity to mechanical energy in two stages.
Turning on the ignition switch releases a small amount of power from
the battery to the solenoid above the starter. This creates a magnetic
field that pulls the solenoid plunger forward, forcing the attached shift
yoke to move the starter drive so that its pinion gear meshes with the
engine's crankshaft flywheel. When the plunger completes its travels,
it strikes a contact that permits a greater amount of current to flow
from the battery to the starter motor. The motor then spins the drive
and turns the meshed gears to provide power to the crankshaft, which
prepares each cylinder for ignition. After the engine starts, the
ignition key is released to break the starting circuit. The solenoid's
magnetic field collapses and the return spring pulls the plunger back,
automatically shutting off the starter motor and disengaging the
starter drive.
When the starter is not in use, the drive unit is retracted
so that its pinion is disengaged from the flywheel. As soon as the starter
is activated, the forward movement of the solenoid plunger causes the shift
yoke to move the drive in the opposite direction and engage the pinion
and flywheel. The pinion is locked to its shaft by a clutch that unlocks
if the engine starts up and the flywheel begins turning the pinion faster
than its normal speed. By allowing the pinion to spin freely for a moment,
the clutch protects the motor from damage until the drive is retracted.
Alternator or Generator
The alternating-current generator, or alternator, is the electrical system's chief
source of power while the engine is running. Its shaft is driven by the same belt
that spins the fan. It converts mechanical energy into alternating-current
electricity, which is then channeled through diodes that alter it to direct
current for the electrical system and for recharging the battery.
Lighting Circuit
The automobile lighting circuit includes the wiring harness, all the
lights, and the various switches that control their use. The complete
circuit of the modern passenger car can be broken down into individual
circuits, each having one or more lights and switches. In each separate
circuit, the lights are connected in parallel, and the controlling switch
is in series between the group of lights and the fuse box. The parking
lights, are connected in parallel and controlled by a single switch. In
some installations, one switch controls the connection to the fuse box,
while a selector switch determines which of two circuits is energized.
The headlights, with their upper and lower beams, are an example of this
type of switch. Again, in some cases, such as the courtesy lights, several
switches may be connected in parallel so that any switch may be used to
turn on the lights.
Main Lighting Switch
The main lighting switch (sometimes called the headlight switch) is the
heart of the lighting system. It controls the headlights, parking
lights, side marker lights, taillights, license plate light, instrument
panel lights, and interior lights. Individual switches are provided for
special purpose lights such as directional signals, hazard warning flashers,
back up lights, and courtesy lights. The main lighting switch may be of
either the "push-pull" or "push-pull with rotary contact" types. A typical
switch will have three positions: off, parking, and headlamps. Some switches
also contain a rheostat to control the brightness of the instrument panel
lights. The rheostat is operated by rotating the control knob, separating
it from the push-pull action of the main lighting switch.
When the main lighting switch completes the circuit to the headlamps,
the low beam lights the way for city driving and for use
when meeting oncoming traffic on the highway. When the dimmer switch is
actuated, the single filament headlamps go "on," along with the high beam
of the two filament headlamps. The next actuation of the dimmer switch
returns the headlighting system to low beams only on the two filament lamps.
Some cars are equipped with an electronic headlight dimming device, which
automatically switches the headlights from high beam to low in response
to light from an approaching vehicle or light from the taillight of a vehicle
being overtaken. The dimmer switch in the automatic headlamp dimming system
is a special override type. It is located in the steering column as part
of a combination dimmer, horn, and turn signal switch. The override action
occurs when a slight pull toward the driver on the switch lever provides
high beam headlights regardless of the amount of light on the sensor-amplifier.
For some years there has been discussion about the advantages
of a polarized headlight system. Such a system comprises headlights which
produce polarized light in a particular plane. The windscreens of all cars
would be fitted with polarizing glass, which would be oriented so that
glare from an approaching vehicle would be essentially eliminated, while
the forward vision would still be kept at the present levels. The advantages
the system appear attractive, but the practical problems of making the
transition are very great, since it would not be practical to convert all
existing vehicles to this type of lighting. Also, any benefits would only
be marginal because glare itself is not a frequent cause of accidents.
However, many cars now have refracting or colored glass to cut down on
glare.
Directional Signal Switch
The directional signal switch is installed just below
the hub of the steering wheel. A manually controlled lever projecting from
the switch permits the driver to signal the direction in which he wants
to turn. Moving the switch handle down will light the "turn signal" lamps
on the left front and left rear of the car, signaling a left turn. Moving
the switch upward will light the turn signal lamps on the right (front
and rear), signaling a right turn. With the switch in a position to signal
a turn, lights are alternately turned "on" and "off" by a turn signal flasher.
Incorporated in the directional signal switch is a "lane change switch
mechanism." This feature provides the driver the opportunity to signal
a lane change by holding the turn lever against a detent, then releasing
it to cancel the signal immediately after the maneuver is completed.
Stoplight Switch
In order to signal a stop, a brake pedal operated "stoplight
switch" is provided to operate the vehicle's stop lamps. In addition to
lighting the conventional rear lights, the switch also operates the center
high-mounted stop lamp, that became mandatory on later models. Cruise control
equipped vehicles may also utilize a vacuum release valve. In this case,
both the vacuum release valve and the stoplight switch are actuated by
movement of the brake pedal.
Horn
The car horn on passenger cars provides the driver with
a means of sounding an audible warning signal. The horn electrical circuit
generally includes: battery, fuse or fusible link, horn relay, horn(s),
steering column wiring harness, horn switch, and body sheet metal. Often,
a cadmium plated screw is used to ground the horn to the body of the vehicle.
Horns usually are located in the forward part of the engine compartment
or in the front fender well. The horn switch is built into the steering
wheel or incorporated into the multi-functional switch lever, which includes
turn signal and dimmer switch.
Transistors and Resistors
A transistor is a solid state device used to switch and/or
amplify the flow of electrons in a circuit. A typical automotive switching
application would be a transistorized ignition system in which the transistor
switches the primary system off and on. An amplifying application could
be in a stereo system where a radio signal needed strengthening.
A transistor is a three-element device made of two semiconductor
materials. The three elements are called "emitter," "base," and "collector."
The outer two elements (collector and emitter) are made of the same material;
the other element (base) is different. Each has a conductor attached. The
materials used are labeled for their properties: "P" for positive, meaning
a lack of electrons. It has "holes" ready to receive electrons. "N" is
for negative, which means the materials has a surplus of electrons. The
movement of a free electron from atom to atom leaves a hole in the atom
it left. This hole is quickly filled by another free electron. As this
movement is transmitted throughout the conductor, an electric current is
created from the negative to the positive. At the same time, the "hole"
has been moved backward in the conductor as one free electron after another
takes its place in a sort of chain reaction. "Hole flow" is from positive
to negative. Current flow in a transistor, then, may be either electron
movement or hole flow, depending on the type of material, and this determines
the type of transistor it is as well.
In most 12 volt systems, a resistor is connected in series
with the primary circuit of the ignition coil. During the cranking period,
the resistor is cut out of the circuit so that full voltage is applied
to the coil. This insures a strong spark during cranking, and quicker starting
is provided. The starting circuit is designed so that as long as the starter
motor is in use, full battery voltage is applied to the coil. When the
starter is not cranking, the resistance wire is cut into the circuit to
reduce the voltage applied to the coil. If the engine starts when the ignition
switch is turned on, but stops when the switch is released to the run position,
it can indicate that a resistor is bad and should be replaced.
At no time should the resistor be bypassed out of the
circuit, as that would supply constant battery voltage and burn out the
coil. The resistor and resistor wires should always be checked when the
breaker points are burned, or when the ignition coil is bad.
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